TRON C@ 50
I ~ Stainle~s
.Best corrosion resistance of all stainless steels
.Exceptionally low magnetic permeability
.Strength almost double Type 316
~ Hi9h Performance Alloys
-444 Wilson St .
= Tipton, IN 46072
Phone: (765)675-8871FAX: (765) 675-7051
Product Data Bulletin
%Min
0.030
4.00
0.20
20.50
11.75
2.00
0.24
0.0008
0.12
0.10
Carbon
ManganesePhosphorusSulfurSiliconChromiumNickel
MolybdenumCopperNitrogenTitaniumAluminumBoronColumbiumTantalumTinVanadium
Tungsten
Available Forms
Data referring to mechanical prop-erties and chemical analyses arethe result of tests performed onspecimens obtaIned from specificlocations of the products in accor-dance with prescribed samplingprocedures: any warranty thereofis limited to the values obtained atsuch locations and by such proce-dures. There is no warranty withrespect to values of the materialsat other locations.
The information and data in thisproduct data bulletin are accurateto the best of our knowledge andbeliet but are intended for generalinformation only. Applications sug-gested for the materials are de-scribed only to help readers maketheir own evaluations and deci-sions. and are neither guaranteesnor to be construed as express orimplied warranties of suitability forthese or other applications.
Armco. the Armco Trlongle. NITRONIG.17-4PH.I5-5PH.17-7PH.ondPHI3-8Moore registered frodemorks of Armco Inc
Hoste"oy ond Hoynes ore frodemorks ofHoynes Intemotionol.
Inconel ond Monel ore trodemorks ofIntemotionol Nickel Go. Inc
2
%Max
0.050
5.50
0.040
0.015
0.60
22.00
13.00
2.50
0.75
0.30
0.020
0.020
0.0025
0.20
0.10
0.030
0.30
0.15
Product Description 2 NITRONIC 50
HPAlloys NITRONIC 50 Stain-less Steel is available in bar,master alloy pigs, ingots andforging quality billets. Formsavailable from other manu-facturers include castings,extrusions, seamless tubingand plate. NITRONIC 50Stainless Steel is covered byU.S. Patent3,912,5Q3.
COm~ositi~n ,.""""..,..., ,2 Stainless Steel
Speclfl~atlons """" 2 Product
Annealing Temperature 3
Metric Practice ...""".""""...3 Description
Mechanical Properties , 3-8 HPAlloys NITRONIC 50Galling/Wear Resistance 9 Stainless Steel provides aPhysical Properties ,.., 9-10 co~bination of corrosion
., resistance and strength notCorrosion ResIstance"...1D-15 found in any other com-Fabrication """" """"...16 mercial material availableForging " 16 in its price range. This
.austenitic stainless steel hasAnne.allng , ",,16 corrosion resistance greater
Welding ", ,."""".,..,,16-17 than that provided by
Machinability,., , 18 Types 316, 316L 317 andCastings ...,." , ,.,...,., 19 317L plus approximatelyCase Histories ..,..,.., 19-BC twiCe tthe yieldt stren lgth at
room empera ure. naddition, NITRONIC 50Stainless Steel has verygood mechanical proper-ties at both elevated andsub-zero temperatures.And, unlike many austeniticstainless steels, NITRONIC 50does not become mag-netic when cold worked orcooled to sub-zero tem-
peratures, High Strength(HS) NITRONIC 50 StainlessSteel has a yield strengthabout three times that ofType 316 stainless steel.
Metric PracticeOther specificationcoverage is pending. It issuggested that HPAlIoys becontacted for informationconcerning additional
coverage.
The newton (N) has beenadopted by the S I as themetric standard uni.tofforceas'discussed in the A1S1Metric Practice Guide. Theterm for force per unit of area(stress) is the newton persquare metre (N/m2). Since
this can be a large number,the prefix mega is used toindicate 1 ,000,000 units and
the term meganewton persquare metre (MN/m2) isused. The unit (N/m2) hasbeen designated a pascal
(Pa). The relationshipbetween the U.S. and the SIunits for stress is: 1000pounds/in2 (psi) = 1 kip/in2
(ksi) = 6.8948 mega-newtons/m2 (MN/m2) =
6.8948 megapascals (MPa).Other units are discussed inthe Metric P.ractice Guide.
Annealing
TemperatureHPAJIoys NITRONIC 50Stainless Steel can besupplied annealed at 1950 F
to 2050 F (1066 C to1121 C). For mostapplications, the 1950 F(1066 C) condition shouldbe selected, as it provides a
higher level of mechanicalproperties along with
excellent corrosionresistance. When as-weldedmaterial is to be used instrongly corrosive media, the2050 F (1121 C) conditionshould be specified in orderto minimize the possibility of
intergranular attack.
Reductionof Area
%
I:longation%in2"
(50.8 mm)
0.2% VS
psi (MPa)UTS
psi (MPa)Condition
5555.000 (379) 35100,000 (690)
Annealed
1950F(1066C)to
2050F(1121 C)and
water Quenched(up to 144 in' [9290cm2])
Over 144 in2 (9290 cm2)
to 324 in' (2091 cm2)453095.000 (655) 50.000 (345}
3
The values shown in thisbulletin were established inlJ.$.. customary units. Themetric equivalents of U.S.customary units shown maybe approximate. Conversionto the metric system, known
as the International Systemof Units (SI), has beenaccomplished in accordancewith the American Iron andSteel Institute Metric Practice
Guide,1978.
Table 1Minimum Properties Acceptable for Material Specification
Annealed Bars
Table 2Typical Room Temperature Properties*1 II (25.4 mm) Diameter Bar
Table 3Typical Short- Time Elevated Temperature Tensile Properties*
UTS
ksi (MPa)
0.2% VS
ksi (MPa)
Reduction of Area
%
Test Temperature
F (C)
I Elongation% in 2" (50.8 mm)Condition
75200400600800
1000120013501500
405
405
375
375
395
365
365
425
595
Annealed
Bars 3/4 t
(191 to 3
Diameter
124 (855)
112 (772)
102 (703)
98 (676)
94 (648)
89 (614)
80 (552)
68 (469)
50 (345)
78 (538)
66 (455)
58(400)54 (372)
50 (345)
48(331)44 (303)
42 (290)
32 (221 )
675
675
67
64
63
625
63
71.5
85
Annealed 2050 F
(1121 C)
Bars1"to1-1/2"
(254 to 38,1 mm)
Diameter
75 (24) 117 (8071
200 (93) 107 (738)
400 (204) 96 (662)
600(316) 92(634)800 (427j 89(614)
1000(538) 84(579)
1200(649) 74(510)
1350(732) I 66(455)1500 (816) 52 (359)
Average of triplicate tests from each of three heats
60 (414)
50 (338)
38 (262)
35 (241 )
34(234)32 (221)
31 (214)
31 (214)
30 (207)
45
435
435
425
43.5
41
3837
41
71
705
695
675
66
665
64
615
61
Table 4
Typical Stress-Rupture Strength*
Stress for Failure, ksi (MPalTest Temp.F (C)Condition 10.000 Hours (estimatedl
Annealed
Bars 314"
(191- 31
Diameter
72 (496)
47 (324)
22 ( 152)
6 (41.4)
1.3 19.0)
Annealed 2050 F 1000 (538)
(1121C) 1100(593)
Bar~ 1" to 1-1/2" 1200(649)
(254-381mm) 1350(732)
Diameter 1500 (816)
.Average of tests from three heats
65 (448)
50 (345)
29 (2001
13 (8961
54 (372)
41 (283)
15 (103)
65(448)
43 (296)
325 (224)
85 (586)
35 (241)
4
(24)
(93)
(204)
(316)
(427)
(538)
(649)
(732)
(816)
1950F
(1066C)01-1/4"
1.8mm!
1950F
(1066CI
to 1.1/4..
Smm)
Table 5
Typical Creep Strength*1" (25.4 mm) Diameter Bar
Table 6Typical Mechanical Properties*Cold Drawn Wire
Reduction
of Area
%
Cold Reduction
%
UTS
ksi (MPa)
0.2% VS
ksi (MPa)
Elongation
% in 4 x D
15 165 ( 1138) 143 (986) 23 56
30 194(1338) 174(1200) 15 49
45 216 (1489) 196 (1351) 11 45
60 234(1613) 216(1489) 9 42
75 246(1696) ,: 234(1613) 8 39
.Average of duplicate tests.
Starting size 114" (635 mm) dia rod annealed at 2050 F (1121 C).
Incommon with other NITRONIC alloys, NITRONIC 50Stainless Steel, when cold reduced 60% or more without in-process anneals, willembrittle very rapidly when exposed ettempereturea in the range of 600to 1000 F (426 to 538 C). Therefore. springs made of NITRONIC50 Stainless Steel should not be given the low-temperature. stress-relief treatment commonly used for austenitic stainless steels.
Table 7Typical Sub-Zero Mechanical Properties*1" (25.4 mm) Diameter Bar -Annealed 2050 F (1121 C)
Test Temp
F (CI
UTS
ksi (MPa)
0.2% VS
ksi (MPa)
Reduction
of Area %Elongation
% in 2" (50.8 mm)
-100 (-73) I 146 (1007)
-320(-196) ! 226(1558)
.Average of duplicate tests
85 (586)128(883)
495
41
65
51
Table 8
Typical Impact Strength1" (25.4 mm} Diameter Bar -Annealed 2050 F (1121 C}
Impact -Charpy V-Notch. ft-Ibs (JITest Temp
F (C) Simulated HAl.
75 (24) 170 (230) II 170 (230)-100 (-731 115(156) , 115(156)
-320(-196) 50 (68) II 50 (68)
.Heat treated at 1250 F (677 C) for 1 hour to simulate the heat-affected zone of heavy weldments.
Average of duplicate tests.
5
Fatigue Strength
Table 17Rotating Beam Fatigue Tests
Fatigue Strength at 10. Reversals of Strel
ksi(MPa}Condition
Tested in Seawater*
Annealed 2050 F
( 1121 CI
1 n dia
(25.4 mm)
42 (290)
Annealed 1950 F
(1066CI
High-Strength (HS) Bars
(Hot Rolled Unannealed)
68 (469) 18 ( 124)
58(4001
44 (303) 15(103)
1" dia
(25.4 mm)
2-1/2" dia
(63.5 mm)
4" dia
I (102 mm) I
.R R Moore specimens tested at room temperature
.McAdam specimens tested .in ambient temperature seawater (11-31 C) at Laaue Corrosion Laboratory.
Wrlghtsville Beach. NC
Tests from one heat for each size and conditionShear Strength
The shear strength ofNITRONIG 50 Stainless Steelin double shear has beendetermined following BoeingAircraft Go. 02-2860,Procedures for MechanicalTesting of Aircraft StructuralFasteners. The results,determined from atypicalheat, are as shown.
Elastic Properties
The elastic properties ofannealed NITRONIC 50 atroom temperature are as
shown.
Notch Sensitivity
Tensile tests were performedat room temperature usingnotched specimens with astress-concentration factorof Kt = 1.3. The following
data at right show HPAloysNITRONIC 50 StainlessSteel is not notch sensitive.
Table 20
Elastic Properties at Elevated Temperatures*
TemperatureF ICI Poisson's Ratio
72(22) 28.9 x 106 (199x1031
200(93) 27.8x106 (192x103)
300(149) 27.0x106 (186x103)
400 (204) 26.1 x 106 (180 x 103)
500(260) 25.3 x 106 (174x1031
600(315) 24.6x1Q6 (170x103)
700 (371) 24.0 x 106 (165 x 103)
*Tests performed on sheet samples in the longitudinal direction using strain gages.
0.312
0.307
0.303
0.299
0.295
0.291
0.288
Table 21Notch Sensitivity
U 1:0 -NotcneO. kSI IM pa)Condition
Annealed 2050 F (1121 C)
Annealed 1950 F (1066 C)
High-Strength (HS) Bars
Average of duplicate tests
1145 (790)
1205 1830)
151 (1041)
155 ( 1069)
1965 (1354)
8
Table 22
Weight Loss of Couple*
mg/1000 cycles
Test Conditions Taber Met-Abrader machine. 500" 0 crossed (90") cylInders. dry. 16-lb load. 105 RPM. room tem-
perature. 120 grit surface finish. 10.000 cycles. degreased. duplicates. weight loss corrected for density differences
Galling and
Wear
Resistance
The galling re~i,stance of
HPAloysNITRONIC 50
Stainless Steel is similar toType 316 or just slightlybetter.
Metal-to-metal wear testsdemonstrate the superiorityof NITRONIC 50 over alloyK-500 despite the higherhardness of the latter.Comparative wear data areshown.
For applications requiringsuperior galling, wear andcavitation resistance coupledwith good corrosion resistance,HPAloysNITRONIC 60Stainless Steel should beconsidered.
Table 23Cavitation Resistance of Annealed NITRONIC 50 Stainless Steel
Table 24
Wire.
Typical Magnetic Permeability at Field Strength of
Condition 50 Oer. (3978 AIm) 100 Oer (7957 A/m) 200 Oer (15.914 A/m)
'004'004'004'004
1004
1003
1004
1004
Annealed
Cold Drawn 27%
Cold Drawn 56%
Cold Drawn 75%
.Average of duplicate tests
Reference: Advances in croyogenicEngineering Materials, Vol. 26 (1980), pp. 37-47.
also occurs with HPAlIoysNITRONIC 33 and NITRONIC40 Stainless Steels, isdependent on temperaturebut not on field strength.Unlike the AISI 300 seriesstainless steels, most HPAlIoysNITRONIC Alloys show nosupermagnetism.
9
Density at 75 F (24 C)7.88 gm/cmJ
.285 Ibs/inJ
Electrical Resistivity at 70 F(21 C) -82 microhm-cm
Magnetic PermeabilityHPAJIoysNITRONIC 50Stainless Steel does notbecome magnetic whenseverely cold worked. Thischaracteristic makes thealloy useful for applicationsrequiring a combination ofexcellent corrosionresistance and low magnetic
permeability.
The magnetic permeabilityof HP.AJoys NITRONIC 50Stainless Steel remains verylow at cryogenic temperatures,but not as low as HPAJIoysNITRONIC 33 and NITRONIC40 Stainless Steels. Themagnetic susceptibility datain Table 25 were obtained onmill-annealed sheet samplesusing the Curie Force Method.
Note that the magneticsusceptibility of HPAHoysNITRONIC 50 Stainless Steelexhibits a cusp atapproximately -400 F ( -240C). This phenomenon, which
Coefficient of Thermal Expansion
Table 26Coefficient of Thermal ExpansionAnnealed Material*
Coefficient of Thermal Expansion
microinches/in/Q F, (!lm/m. K)Temperature Range
F (C)
90
92
9.6
9.9
10.2
105
10.8
11.1
(16.2)
(16.6)
(17.3)
(17.8)
(18.4)
(189)
(19.4)
(20.0)
70-200 (21-93)
70-400 (21-204)
70-600 (21-316)
70-800 (21-427)
70-1000 (21-538)
70-1200 (21-649)
70-1400(21-760)
70-1600(21-871)
Average of duplicate tests
Table 27Thermal Contraction
Corrosion
Thermal Conductivity
Table 28
Thermal Conductivity.
BTU/hr/ft2/in/OF (W/m.K)lemperature
F (CI
(15.6)
(17.91
(20.3)
(23.01
(25.2)
108
124
141
160
175
70 (21)
300 (149)
600(316)
900(482)
1200(649)
1500 (816)
.Average of duplicate tests
10
ResistanceHPAlloys NITRONIC 50Stainless Steel providesoutstanding corrosionresistance -superior toTypes 316, 316L, 317 and317L in many media. Formany applications the1950 F ( 1066 C) annealedcondition provides adequatecorrosion resistance and ahigher strength level. In verycorrosive media or wherematerial is to be used in theas-welded condition, the2050 F (1121 C) annealedcondition should be
specified. High-Strength(HS) NITRONIC 50 bars areuseful for applications suchas shafting and bolting, butdo not quite exhibit thecorrosion resistance of theannealed conditions in allenvironments.
Typical corrosion ratesobtained from laboratorytests on NITRONIC 50Stainless Steel in its severalconditions are shown inTable 29 along withcomparable data for Types316, 316L, 317 and 317Lstainless steels.
Table 29
Laboratory Corrosion Test Data
Corrosion Rates in Inches per Year IIPY) Unless Otherwise Indicatedl11
NITRONIC 50 Bar
Annealed 1950 F
(1066 C)
NITRONIC 50 Bar
Annealed 2050 F
(1121C)
I NITRONIC 50
High-Strength(HS) Bar(31
Types 316 &316L I
Annealed Bar I
Types 3'7 &3'7L
Annealed Bar
Test Medium
10% FeCIJ.25 C -plainl21
10% FeCIJ.25 C_~eviced{21
< .001 g/in2
< 001 g/in2
< .001 g/in2
< 001 g/in2
011 g/in2
186 g/in2 -
1% H2SO4' 80 C
2% H2SO4' 80 C
5% H2SO4' 80 C
10% H2SO4' 80 C
20% H2SO4' 80 C
Table 31Intergranular Corrosion Resistance of Cast NITRONIC 50
Huey Test. JPM
% FerriteAnnealed *
0.00060.0015
0.0005
0.0004 I ---~
.2050F(1121 C).112-Hour.WaterQuenched..2050 F ( 1121 C) .112.Hour .Water Quenched + 1250 F (677 C) -112-Hour -Air Cooled.
Even sensitized cast NITRONIC 50 stainle.s Steel has an acceptable intergranular corrosion rataless than 0.0020 IPM with up to
4% farrita presant.
Table 32Intergranular Attack Resistance of NITRONIC 50 Bar
per ASTM A262
Intergranular Attack
The resistance of HPAlIoysNITRONJC 50 Stainless Steelto intergranular attack isexcellent even when sensitizedat 1250 F (675 C) for onehour to simulate the heat-affected zone of heavyweldments. Material annealedat 1950 F (1066 C) has verygood resistance tointergranular attack for mostapplications. However, whenthick sections of HPAlIoysNITRONIC 50 Stainless Steelare used in the as-weldedcondition in certain stronglycorrosive media, the 2050 F
(1121 C) condition givesoptimum corrosion resistance.This is illustrated by Table 32.
Practice E
Copper-Copper SulfateCondition
0.00101PM0.0038 IPM
Passed
Passed
Annealed 1950 F ( 1066 C)
Annealed 1950 F ( 1066 C)
+ 1250F(677C)-
1 hr.-A.C.
Annealed 2050 F ( 1121 C)
Annealed 2050 F ( 1121 C)
+ 1250F(677C)-
1 hr.-A.C.
High-Strength (Bar Mill)
High-Strength (PRF)
Edge
Intermediate
Center
0.0009 IPM0.00221PM
Passed
Passed
0.0031 IPM Passed
0.00131PM
0.0012 IPM
0.0011 IPM
Passed
Passed
Passed
Stress-CorrosionCracking Resistance
In common with moststainless steels, under certainconditions, HP.AJIoys NITRONIC50 Stainless Steel maystress-corrosion crack in hotchloride environments. Whentested in boiling 42% MgCI2solution, a very acceleratedtest, NITRONIC 50 StainlessSteel is between types 304and 316 stainless steels inresistance to cracking. Thereis little difference insusceptibility to crackingwhether in the annealed,high-strength (HS), or cold-drawn conditions. This isillustrated by the comparativedata in Table 33 using thedirect-Ioaded tensile-type testmethod (described in detail
in ASTM STP 425, September1967). Note that this is asevere test, especially atthese temperatures. Formarine applications, thefollowing better reflects theresistance of NITRONIC 50
Stainless Steel:
U-bend-type stresscorrosion test specimens ofNITRONIC 50 in the followingmetallurgical conditions havebeen exposed to marineatmosphere on the 80' lot atKure Beach. N.C.
(1) Mill Annealed 1950 F
(1063 C)(2) Mill Annealed &
Sensitized 1250 F (675 C)(3) Cold Rolled 44% (160
ksi yield strength)Tests were begun on June
3. 1970. No failure occurredafter 15 years exposure.
12:
and chokes for valve shafts.stems and pins, providedthis cold working ispreceded by an anneal.
Table 34 illustrates theresistance of HPAlloysNITRONIC 50 Stainless Steelto cracking in laboratorytests in synthetic sour-wellsolution (5% NaCI + 1/2%acetic acid, saturated withH2S). Comparable data areincluded for HPA8oys 17-4 PHStainless Steel, which isconsidered acceptable byNACE for use in sour-wellservice in the two heat-treated conditions shown.
Sulfide Stress
CrackingBoth laboratory tests andfield service experienceshow that HPAloys NITRONIC50 Stainless Steel hasexcellent resistance to sulfidestress cracking in allconditions. NITRONIC 50Stainless Steel in both theannealed and high-strength(hot-rolled) conditions hasbeen included in the 1988revision of NACE StandardMR-01-75, "Sulfide StressCracking Resistant Materialfor Oil Field Equipment,' , at
hardness levels up to RC35maximum. The cold-workedcondition to RC35 maximumalso is acceptable in valves
Table 34
Resistance to Sulfide Stress Cracklng(1)
Time to Failure. hr.. Under Stress. ksi (MPal-~
Hardness
Rockwell
0.2% VS
ksi (MPa)
160 / 140(1034) (965)
125(862)
100
(690)
76(617)
50
(345)
25
(172)Alloy Condition
>1000C22 67 (448) >1000 >1°001
C33 135 (931) 2041 3201>1000 >1000
C35 146 (1007) 3581
C36 144 (993) 170121 , >10001 >10001>1000
C4 1160 (1103) >100°1 >1000
17-4 PH
17-4 PH
C32.5
C29
9.5
13.5
16
29
225
850
10 (758) est.
85 (586)
It)Longitudinal tensile specimens tested according to NACE TM 01-7712) Ductile creep failure.
131 For hot rolled bars only.
NITRONIC 50 StainlessSteel spring temper wirecoiled into a spring wasexposed to the NACEsolution at room temperatureunder the following conditions:
13
H 1150+ 1150
H 1150-M
Alloy 400 (Ni-Cu)NITRONIC 50
Wood BlockWood Block
Seawater Resistance
Here is how NITRONIC 50
High-Strength (HS) shaftingand Alloy 400 (Ni-Cu) lookedafter 18 months' exposure inquiet seawater off the coastof North Carolina. The testwas conducted without zincanodes to establish therelative corrosion resistanceof NITRONIC 50 High-3trength(HS) shafting. Had zincanodes been us~d or abronze propeller fitted tothese bars, no crevicecorrosion should haveoccurred. The photographwas taken after barnaclesand other forms of marinelife were cleared from thetest bars.
Before exposure, allspecimens were polished tc
120 grit finish, degreasedand passivated. They werethen clamped into pepper-wood racks and exposedfully immersed in seawater.NITRONIC 50 high-strength(HS) shafting showed nocrevice attack under thewooden blocks after the 18months. One bar ofNITRONIC 50 high-strength(HS) shafting remainedperfect, while the othershowed a few areas of verylight crevice attack, < .001 "
(0.025 mm) deep undermarine attachments. Bothsamples of.Alloy 400suffered shallow creviceattack .001 "-.003"
(0.025-0.076 mm) deepunder the area in contactwith the wooden rack, andalso under numerousattached barnacles.
Type 316 stainless steeltested similarily for ninemonths suffered randompitting and crevice corrosionunder the area in contactwith the wooden rack andalso under marineattachments, whileNITRONIC 50 againremained in perfectcondition. These specimensare shown in the photograph.
These two bars are immersed in quiet seawater for nine months.Bright shiny bar at right is HP.Ai7Js, NITRONIC 50 stainless steel, andat left is Type 316 stainless steel showing considerable pitting and
crevice corrosion.
14
Pitting ResistanceSalt Fog -MarineEnvironment
No change was apparent inNITRONIC 50 Stainless Steelin any condition after exposureto 5% NaCI fog at 35 C for500 hours, or after exposureto marine atmospheres onthe 800-foot (24.4m) lot atKure Beach, North Carolina,for 7V2 years. Similar exposureto marine atmospheresproduces light staining onType 316 stainless steel.
Food Handling
HPAlloys NITRONIC 50Stainless Steel is consideredsuitable for food contact use.The National SanitationFoundation includes HPAlloysNITRONIC 50 Stainless Steelin their .'List of AcceptableMaterials for Food ContactSurfaces."
These pieces of bar were all exposed to 10% ferric chloride solutionfor 50 hours at room temperature. A rubber band was placedaround each to promote crevice corrosion which sometimes occursin areas where the surface is shielded from oxygen. From left toright, they are HP.AJk1,IS N ITRON IC 50 Stainless Steel, Type 316stainless steel and Type 304 stainless steel. OnlyHP.AJkr,'sNITRONIC 50 stainless is still bright and shiny. The Type 316 andType 304 stainless steels are badly pitted and show severe crevicecorrosion in the area where the rubber bands were placed.
Poly thionic Acid
Resistance
Poly thionic acids are of the
general formulaH~xO6.where x is usually 3, 4 or 5.These acids can form readilyin petroleum refinery units,
particularly desulfurizers.during shutdown.
Stressed U-bendspecimens of NITRONIC 50stainless, in both theannealed condition and aftersensitizing at 1250F (677 C)for 1 hour, showed no traceof cracking after exposure topoly thionic acids for 500hours at room temperature.
Type 304 Type 316 NITRONIC 50
photograph, Type 304stainless steel becameseverely etched in two weeksand Type 316 stainless steelshowed some corrosiveattack in all exposed areasafter six weeks. HPAlloysNITRONIC 50 Stainless Steelremained unaffected after sixweeks' exposure to thisaggressive medium.
HPAlloysNITRONIC 50Stainless Steel is presentlybeing specified for the blocks,plungers and related parts ofreciprocating pumps whenservice requires handlingammonium carbamate orother corrosive materials.
Urea Production
Ammonium carbamate -anintermediate producedduring the manufacture ofurea- is extremelycorrosive to processequipment. Pump parts inthe process are subjected toa combination of severecorrosive attack, hightemperatures and cyclical
operating pressures rangingup to 3000 psi. Some partsmade of Type 316L stainlesssteel have shown surfaceattack in just a few months.
A manufacturer of specialvalves tested three stainlesssteels in ammoniumcarbamate. As shown in the
15
Table 36
Nominal Composition and Typical Mechanical Propertiesof Several Austenitic All-Weld-Metal Deposits
Fabrication
Filler Metals
Filler metal, when added tothe joint, should be HPABoysNITAONIC 50W (AWS E/EA209), a matching filler metalcomposition that providescomparable strength andcorrosion resistance to thebase metal. However, soundweld joints may also beobtained using theconventional austeniticstainless steel fillers such asTypes 308L and 309. Whenusing these more commonfiller metal compositions,allowances should be madefor the strength andcorrosion differences.
Nominal compositions andrepresentative mechanicalproperties are shown for themore common electrodefiller rods in Table 36. Theweld metal alloys are listedgenerally in the order of(a) increasing alloy content,(b) increasing strength level,(c) increasing corrosionresistance and (d) increasingcost.
These data show that thehighest strength levels withgood tensile ductility andalloy elements that impartgood corrosion resistanceare provided by the HP.AJIoysNITAONIC 50W Electrode. Insome specific applicationswhere the high strength
16
Although HPAlloys NITRONIC50 Stainless Steel isconsiderably stronger thanthe conventional 300 seriesstainless steels, the samefabricating equipment andtechniques can be used.
NITRONIC 50 Stainless Steelis readily forged like Type 316stainless steel, except that itrequires more power and thetemperature is 2150 F to2250 F (1177 C to 1232 C).
Like other austenitic stainlesssteels, NITRONIC 50 mustbe rapidly cooled. In-processanneals to facilitate coldforming should be done at2050 F (1066 C). Pleasenote Page 3.
In addition to the improvedmechanical properties andcorrosion resistance, HPAlloysNITRONIC 50 Stainless Steelcan be welded successfullyby using any of theconventional weldingprocesses that are normallyemployed with the austeniticstainless steels.
HPAlloys NITRONIC 50Stainless is readily arcwelded in all forms. As withmost austenitic stainlesssteels, good weld jointproperties can be obtainedwithout the necessity ofpreheat or post-weldannealing. Good shielding ofthe molten weld puddle isimportant to prevent anyabsorption of nitrogen fromthe atmosphere that couldresult in porosity.
Autogenous, high-powerdensity joining processessuch as electron beam (EB)and laser welding should beused with caution due to thelow FN potential of the basemetal (FN approximately 2).Field reports also indicatethe possibility of severeoutgassing during EB weldingin a vacuum atmosphere.Under vacuum conditions,this outgassing is to beexpected for liquid weldmetal containing a highnitrogen level.
Table 37
Typical Mechanical PropertiesHPAlloys NITRONIC 50 Stainless Plate Weld Joints
Weld
Filler
UTS
ksi (MPa)
0.2% VS
ksi (MPal
Elong,% in2"
Red. in
Area. %
Failure
Location
--Weld
Process
Shielded
Metal Arc
(SMA)
Gas Metal
Arc (GMA)
Spray
36NITAONIC SOW 113 (779) 76 (524) 20 WeldMetal
112(772) 77 (531) 21 30 WeldMetal
NITRONIC SOW
levels or superior corrosionresistance in the welddeposits are not required,other filler metals can beused to advantage becauseof reduced costs and/orready availability.
The matching weld filler(NITAONIC 50W, AWS E/EA209) for HPAloys NITAONIC50 Stainless Steel is similarto many of the regularaustenitic stainless steel fillermetals in that a smallpercentage of the magneticferrite phase has beenintroduced to assure soundweld deposits. The smallquantity of the second phaseusually produces a magneticpermeability value ofapproximately 1.2 inshielded metal-arc welddeposits. This correspondsto a ferrite number (FN) ofapproximately 6.
Highly overalloyed Ni basefillers are suggested forapplications requiring highresistance to pitting media orvery low as-depositedmagnetic permeability.
Heavy Section WeldJoint Properties
The mechanical properties ofwelds in 1-1/4" (32.1 mm)thick plate have beendetermined using two weldprocesses that are normallyemployed in heavy sectionwelding, namely, (a) shieldedmetal arc (SMA) or stickelectrode welding and (b)gas metal arc (GMA) or MIGwelding wit!l the spray mode.Typical test values that canbe expected from tensilesamples cut transverse to theweld centerline are shown inTable 37.
Heat input is important inobtaining the most satisfactoryweld joint. Narrow stringerbeads rather that a wide"weave" technique shouldbe used for highest weldductility. Good shielding ofthe molten puddle is importantto eliminate additional nitrogenfrom the atmosphere thatcould cause porosity. Bothstringer beads and adequateshielding are normal factorsin good stainless steel
welding practice.
Resistance WeldingAlthough no direct resistancewelding experience hasbeen obtained with HPAlloysNITRONIC SO StainlessSteel, the similarity of thealloy to HPAlloys NITRONIC 40Stainless Steel suggests agood response to resistancespot welding and cross-wirewelding techniques. Thewelding schedules outlinedin the fabricating bulletin,"Welding HPAlloys StainlessSteels: ' can be used as a
guide to produce sound,high-strength joints in bothannealed and cold-reducedsheet. Average shearstrength data for spotwelded joints in HPAlloysNITRONIC 40 Stainless Steelappear in the Product Data
Bulletin, "HPAlloysNITRONIC40 Stainless Steel Sheet andStrip." HPAloys NITRONIC SOStainless Steel is expected toperform in a similar manner.
For more specificsuggestions and for NITRONICSOW filler metal sources,contact Baltimore SpecialtySteels Corporation.
GTA Weld Joints
Gas tungsten arc weld jointshave been fused successfullyin several flat-rolled thicknessesof HPAlloys NITRONIC 50Stainless Steel. Mechanicalproperty values similar tothose of the base metal havebeen obtained in the as-welded condition.
The corrosion resistance ofGTA welded joints has beenevaluated using the standardHuey test (ASTM A 262,Practice C) for detectingintergranular attack instainless steels. Laboratorytest experience shows thatwelds made using theNITRONIC 50W StainlessSteel filler metal exhibit thesame resistance tointergranular attack as thebase metal.
17
Table 38
Machinability*
100%
., " 0 (254 mm)-annealed-RB 95
Five-hour form tool life using high-speed tools
Data based on duplicate tests
Table 39
Recommended Machining Rates for NITRONIC 50
Cutting Rates. SFMMachining Operation
40-65
40-65
90-140120-190
50-6550-75
Automatic Screw Machine
Heavy duty Single or Multiple Spindle and Turret Lathe
High Speed Tools Rates may be increased 15-30% with
High-Cobalt or Cast Alloys
lI.utomatic Screw Machine (Swiss Type)
Cast Alloy or Carbide Tools
:5ingle Point Turning
Carbide Tools
Roughing
FinishingHigh Cobalt or Cast Alloy Tools
Roughing
FinishingHigh-Speed Steel Tools
Roughing
Finishing
30-45
50-60
15-40
40-60
10-25
30-50
Milling (When using end mills, use two-fluted
type and shorten it 25%)
ReamingSmooth Finish
Work Sizing
High-speed steel reamers Greatly increased rates
obtainable with carbide tooling
Threading and Tapping
DrillingHigh-speed Drills
18
HPAlloys NITRONIC 50Stainless Steel has machiningCharacteristics similar to otheraustenitic stainless steels. Itis suggested that coatedcarbides be considered whenmachining all NITRONICalloys, since higher cuttingrates may be realized.NITRONIC 50 Stainless Steelis more susceptible to coldwork hardening than types304 and 316 stainless steels.Also, the alloy has higherstrength. Machining testsshow the alloy to machineat approximately 21% of thecutting rate for B1112. Thismeans NITRONIC 50 StainlessSteel can be machined atapproximately 1/2 the cuttingrate (SFM) used for Type 304or 316 stainless steels, basedon using high-speed toolsteels. For that reason, asstated above, coated carbidesare recommended for bestresults.
Because of the highstrength of NITRONIC 50Stainless Steel, more rigidtool and work holders thanused for Types 304 and 316stainless steels should beused. Care should be takennot to allow tools to slideover the alloy. Positive cuttingaction should be initiated assoon as possible. The alloyprovides a good surfacefinish.
Table 40Typical Room Temperature and Short.Time Elevated TemperatureProperties of Cast NITRONIC 50 Stainless Steel (CG6MMN) Annealed*
0.2% VS
ksi (MPa)
Reduction%
Text Temperature
F (C)
Elongation
% in 2" (50.8 mm)
75 (24) 93(641)
200 (93) 84 (579)
400(204) 74(510)
600(316) 67(462)
800 (427) 65 (448)
1000 (538) 60 (414)
1200 (649) I 54 (3721
Average of three heats. two tests per heat.
50 (345)
39 (269)
30 (207)
27 ( 186)
27 (186)
25 (172)
24 (166)
48475049474643
46575448555155
Surface dia. One valve manufac-turer found NITRONIC 50Stainless Steel met theneeds better than Type316 stainless, and adoptedthe material as the stan-dard for this precision
part.Mounted in the bodies
of the company's 30-, 36-,and 48 inch valves, theNITRONIC 50 Stainless Steelrings give the body seat apositive seal with excellentfinish and high resistanceto cavitation and crevicecorrosion. The materialalso provides high resis-tance to mechanical
damage.
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'i: !.L\~..i.~:;.(~+i, t. ,.;..Ia;~..'H. '..~ ...;. .,i:'.~ ., ~.. '. ~..;:-;.;.,~c:~, \ .".,, ~. "" '. '.~-.J,;" -~~." ..
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'9
HPAlloys NITRONIC 50Stainless Steel may bereadily cost by all conven-tional techniques. Castingsshould be annealed at2050F ( 1121 C) for 1 /2-hourand water quenched inorder to attain a high levelof corrosion resistance, CastNITRONIC 50 Stainless Steelis listed as Grade CG6MMNin ASTM A 351/351M andA 743.
A manufacturer of valvesfor gas wells testedNITRONIC 50 Stainless Steelagainst the material previ-ously used. HPAlloysNITRONIC 50 Stainless SteelShafts delivered theneeded extra corrosionresistance without sacrific-
ing strength.Seal rings for some
high-performance indus-trial butterfly valves oper-ating at 350 psi must havehigh hardness plus superiorcorrosion resistance tomeet the demands of avariety of chemical me-
NITRONIC 50 shows better resistance than T ypes 316 and316L to pitting and crevice corrosion by sour oil and gasfluids, plus much higher strength. It is included in NACEMR-Ol-75 in both the annealed and high-strength barconditions.
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department of HPA has over 50 years
experience in technology, product
development, and sales-marketing of
specialty materials. High Performance
Alloys is qualified to help you in
impartially selecting the cost effective
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